Soft Routes to Inorganic Frameworks Via Assembly of Molecular Building Blocks
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SOFT ROUTES TO INORGANIC FRAMEWORKS VIA ASSEMBLY OF MOLECULAR BUILDING BLOCKS Balamurugan Kandasamy A Thesis Submitted for the Degree of PhD at the University of St Andrews 2012 Full metadata for this item is available in St Andrews Research Repository at: http://research-repository.st-andrews.ac.uk/ Please use this identifier to cite or link to this item: http://hdl.handle.net/10023/3120 This item is protected by original copyright Soft Routes to Inorganic Frameworks via Assembly of Molecular Building Blocks Balamurugan Kandasamy This thesis is submitted in partial fulfilment for the degree of Doctor of Philosophy in the faculty of science of the University of St Andrews November 2011 1. Candidate’s declarations: I, ……, hereby certify that this thesis, which is approximately ….. words in length, has been written by me, that it is the record of work carried out by me and that it has not been submitted in any previous application for a higher degree. I was admitted as a research student in [month, year] and as a candidate for the degree of …..…. in [month, year]; the higher study for which this is a record was carried out in the University of St Andrews between [year] and [year]. (If you received assistance in writing from anyone other than your supervisor/s): I, …..., received assistance in the writing of this thesis in respect of [language, grammar, spelling or syntax], which was provided by …… Date …… signature of candidate ……… 2. Supervisor’s declaration: I hereby certify that the candidate has fulfilled the conditions of the Resolution and Regulations appropriate for the degree of ……… in the University of St Andrews and that the candidate is qualified to submit this thesis in application for that degree. Date …… signature of supervisor ……… 3. Permission for electronic publication: (to be signed by both candidate and supervisor) In submitting this thesis to the University of St Andrews I understand that I am giving permission for it to be made available for use in accordance with the regulations of the University Library for the time being in force, subject to any copyright vested in the work not being affected thereby. I also understand that the title and the abstract will be published, and that a copy of the work may be made and supplied to any bona fide library or research worker, that my thesis will be electronically accessible for personal or research use unless exempt by award of an embargo as requested below, and that the library has the right to migrate my thesis into new electronic forms as required to ensure continued access to the thesis. I have obtained any third-party copyright permissions that may be required in order to allow such access and migration, or have requested the appropriate embargo below. The following is an agreed request by candidate and supervisor regarding the electronic publication of this thesis: (iii) Embargo on both [all or part] of printed copy and electronic copy for the same fixed period of 2 years (maximum five) on the following ground(s): publication would preclude future publication; Date 12/1/12 signature of candidate …… signature of supervisor ……… A supporting statement for a request for an embargo must be included with the submission of the draft copy of the thesis. Where part of a thesis is to be embargoed, please specify the part and the reasons. Acknowledgements Primarily, I would like thank to my supervisor Dr. John Errington who introduced me to the fascinating field of Polyoxometalates. His guidance, understanding and constant support throughout my time at Newcastle University will never be forgotten. I sincerely thank to Prof. Peter .G. Bruce FRS, University of St. Andrews for offered me PhD studentship and arranged DHPA award for my three years PhD work. I thank to School of Chemistry, University of St.Andrews and Newcastle University for giving me permission to commence this thesis, to do the necessary research work and for the use of the departmental facilities. I thank to Prof. William Clegg and Dr. Ross Harrington, Newcastle University for determining the crystal structures. I also thank Dr. Corrine Wills and Prof. William McFarlane, Newcastle University for their advice regarding NMR spectroscopy, numerous spectra, variable temperature NMR, multinuclear NMR, 2D EXSY NMR and special INEPT experiment. I also thank Prof. Josep Poblet, Universitat Rovira, Spain for computational studies and my thanks continues to Prof. Andrew Houlton and Dr. Ben Horrocks, Newcastle University for allowing me to carry out surface chemistry work. I am also thankful to Dr. Corinne Wills for correcting my PhD thesis, Dr. Scott Watson for AFM measurement, Richard Baron for elemental analysis, Dave Dunbar for ESIMS analysis, Gary for mechanical work, and Chris and William for glass blowing work. I also thankful to my lab mates Mr. Paul Middleton and Dr. Gavin Harle for being extremely helpful and training me in laboratory work, and many masters and bachelor students who have made my time in Bedson Building unforgettable. Finally, I wish to thank my family particularly my parents Mr. Kandasamy and Mrs. Kasthuri and my loveable sisters Sangeetha Ramesh and Dhanalakshmi Anandan for their continuous encouragement and selfless support. I am also grateful to all my Newcastle friends who stayed with me for past three years. Last but not least, I thank to my longstanding ever green friend “Lord Ganesh” by dedicating this entire work to him for giving me the continuous blessings. Contents Page i) Abbreviations ii) Abstract Chapter 1. Introduction Aims and general background 2 1.1 Soft routes to metal oxides 4 1.2 Overview of sol-gel process 5 1.3 M-O-M formation 9 1.4. Polyoxometalates 14 1.5. Types of polyoxometalates 1.5.1 Keggin polyoxometalates 15 1.5.2. Lindqvist polyoxometalates 17 1.6. Functionalisation of Lindqvist polyoxometalates 1.6.1. By using organic ligands 19 1.6.2. By using heterometals. 20 1.7. Metal oxide thin films on functionalised surfaces 1.7.1. By using metal alkoxides 22 1.7.2. By using polyoxometalates 23 1.8. Applications of sol-gel process 24 1.9. Applications of polyoxometalates 25 1.10. Synthesis of POMs in non-aqueous media 27 1.11 Analytical techniques 29 References 35 Chapter 2: Synthesis and Hydrolysis of Metal Halide and Alkoxide Building Blocks 2.1. Introduction 41 2.2 Background 41 2.3. Results and discussion n- 2.3.1. Synthesis of metal hexahalides [MCl6] M = Ti, Sn, Nb 45 2- 2.3.2. Hydrolytic studies of [MCl6] (M = Ti, Sn) 46 2- 2.4. Attempted synthesis of hexaalkoxometalates [M(OMe)6] M=Ti, Sn) 51 2- 2.5. Attempted synthesis of hexahydroxometalates [M(OH)6] 56 2.6. Synthesis of niobium pentamethoxide 57 2.7. Synthesis of niobium chloroalkoxides 58 2.8. Attempted synthesis of cationic alkoxoclusters 66 i 2.9. Synthesis of [Sb(O Pr)5(NH3)] 68 2.10. Synthesis and characterisation of Lindqvist POM’s in non-aqueous media 70 2.11. Attempted synthesis of Q2[(MeO)SbW5O18] 72 2.12. Attempted synthesis of Q3[(MeO)GeW5O18] 72 References 83 3- Chapter 3: Synthesis and Solution Chemistry of [(MeO)SnW5O18] 3.1 Introduction 85 3.2 Background 85 3.3 Results and discussion 3- 3.3.1 Synthesis and characterisation of (TBA)3 [(MeO)SnW5O18] 89 3- 3.3.2 Solution studies of [(MeO)SnW5O18] 91 3- 3.4. Hydrolysis of [(MeO)SnW5O18] 106 3- 3.5. Equilibrium studies of [(OH)SnW5O18] 113 3.6. Attempted synthesis of (TBA)6[(µ-O)(SnW5O18)2] 114 3.7. Attempted ‘direct’ synthesis of (TBA)3[(OH)SnW5O18] 116 3- 3.8. Reaction of [(MeO)SnW5O18] with concentrated HCl 123 3- 3.9. Ligand exchange reactions of [ClSnW5O18] 124 References 129 3- Chapter 4: Reactivity of [XSnW5O18] (X=MeO, OH, Cl) Polyoxometalates 4.1 Introduction 132 4.2 Results and discussion i t 4.2.1 Reaction between [TBA]3[(MeO)SnW5O18] and ROH (R = Et, Pr, Bu) 135 4.2.2 1H NMR studies of Alkyloxido derivatives 137 4.2.3. 13C NMR studies of Alkyloxido derivatives 140 4.2.4. 119Sn NMR studies of Alkyloxido derivatives 141 4.2.5. 17O and 183W NMR studies 142 4.3. Reaction between (TBA)3 [(MeO)SnW5O18] with ArOH (Ar=Ph, p-CH3-C6H4, p-(CH3)3C-C6H4-) 143 4.4. Reaction between (TBA)3 [(MeO)SnW5O18] with ArOH (Ar = m-OH-C6H4, p-OH-C6H4-) 4.4.1. With resorcinol 148 4.4.2. With hydroquinone 149 4.5. Reaction between salicyaldehyde and (TBA)3[(MeO)SnW5O18] 151 4.6. Attempted preparation of extended metal oxides 153 4.7. Infra-red spectroscopy 156 4.8. Crystal structures and mechanism 158 3- 4.9. Reactions of [ClSnW5O18] 4.9.1. Halide abstraction reaction 161 4- 4.9.2. Attempted preparation of [(µ-O)(SnW5O18H)2] 162 4.9.3. Reaction between (TBA)3 [ClSnW5O18] and H2O, MeOH and PhOH 162 4.9.4. With diisopropyl amine 163 4.10. Attempted synthesis of di-tin tetratungstate species 166 References 177 Chapter 5: Immobilisation of Titanium Alkoxides and SnW5 Polyoxometalates on Functionalised Si(111) surfaces. 5.1. Introduction 180 5.2. Atomic layer deposition 181 5.3. Results and discussion 5.3.1. Synthesis of ~ 30% OH functionalised Si(111) surfaces 183 5.3.2. Reaction with metal alkoxides 183 5.3.3. Reaction with polyoxometalate 185 i 5.4. Synthesis of Ti12O16(OPr )16 188 References 192 Appendix 193 Abbreviations 1. Spectroscopic FTIR Fourier Transform Infra Red s Small m Medium w Weak (br) Broad NMR Nuclear Magnetic Resonance INEPT Insensitive Nuclei Enhanced by Polarization Transfer s Singlet d Doublet t Triplet q Quartet m Multiplet ppm Parts per Million Chemical shift 2.